Synthesis of a novel porous organic polymer containing triazine and cyclohexanone rings as an efficient methyl red adsorbent from aqueous solutions

Thiol-maleimide click reaction-driven imprinted polymer for chiral resolution of indoprofen

Indoprofen (INP) comprises two enantiomers, R- and S-, whose high pharmacological efficacy is realized only in the case of the separated enantiomers. A newly synthesized poly(acrylonitrile-co-divinylbenzene) (PANB)-based sorbent with selective affinity to the S-enantiomer of INP was applied to separate INP racemate. The synthesis was performed by suspension polymerization with low-crosslinked PANB microparticles and by reaction of the inserted nitriles with 1-amino-1H-pyrrole-2,5‑dione (Ma-NH2). The cationic maleimide-hydrazidine was then attached to the polymer particles, followed by its loading with anionic S-INP. In the post-crosslinking, ethane-1,2-dithiol (ETH) was used as a crosslinker through a thiol-maleimide click reaction, which attached the ETH to the maleimide groups in Ma-P. Acidic elution released S-INP enantiomers through specific receptor sites formed in the imprinted polymer particles, S-INP-P. Characterization of the polymers was done by Fourier transform infrared spectroscopy (FTIR), nuclear magnetic resonance (13C NMR), and X-ray diffraction (XRD) while the surface morphology of the sorbents was investigated by scanning electron microscope (SEM). Optimum conditions for the enantioselective adsorption indicated that at pH 7, 285 mg/g of S-INP can be extracted. The chiral separation of the INP racemate led to an ee of 85% for R-INP in the first run and 97% for S-INP during elution.

Design and synthesis of S-citalopram-imprinted polymeric sorbent: Characterization and application in enantioselective separation

The current work describes the efficient creation and employment of a new S-citalopram selective polymeric sorbent, made from poly(divinylbenzene-maleic anhydride-styrene). The process began by using suspension polymerization technique in the synthesis of poly(styrene-maleic anhydride-divinylbenzene) microparticles. These were then modified with ethylenediamine, developing an amido-succinic acid-based polymer derivative. The S-citalopram, a cationic molecule, was loaded onto these developed anionic polymer particles. Subsequently, the particles were post-crosslinked using glyoxal, which reacts with the amino group residues of ethylenediamine. S-citalopram was extracted from this matrix using an acidic solution, which also left behind stereo-selective cavities in the S-citalopram imprinted polymer, allowing for the selective re-adsorption of S-citalopram. The attributes of the polymer were examined through methods such as 13C NMR, FTIR, thermogravemetric and elemental analyses. SEM was used to observe the shapes and structures of the particles. The imprinted polymers demonstrated a significant ability to adsorb S-citalopram, achieving a capacity of 878 mmol/g at a preferred pH level of 8. It proved efficient in separating enantiomers of (±)-citalopram via column methods, achieving an enantiomeric purity of 97 % for R-citalopram upon introduction and 92 % for S-citalopram upon release.

A review on carbon-based biowaste and organic polymer materials for sustainable treatment of sulfonamides from pharmaceutical wastewater

Frequent detection of sulfonamides (SAs) pharmaceuticals in wastewater has necessitated the discovery of suitable technology for their sustainable remediation. Adsorption has been widely investigated due to its effectiveness, simplicity, and availability of various adsorbent materials from natural and artificial sources. This review highlighted the potentials of carbon-based adsorbents derived from agricultural wastes such as lignocellulose, biochar, activated carbon, carbon nanotubes graphene materials as well as organic polymers such as chitosan, molecularly imprinted polymers, metal, and covalent frameworks for SAs removal from wastewater. The promising features of these materials including higher porosity, rich carbon-content, robustness, good stability as well as ease of modification have been emphasized. Thus, the materials have demonstrated excellent performance towards the SAs removal, attributed to their porous nature that provided sufficient active sites for the adsorption of SAs molecules. The modification of physico-chemical features of the materials have been discussed as efficient means for enhancing their adsorption and reusable performance. The article also proposed various interactive mechanisms for the SAs adsorption. Lastly, the prospects and challenges have been highlighted to expand the knowledge gap on the application of the materials for the sustainable removal of the SAs.